Supplying build material

ABSTRACT

According to one example there is provided an apparatus for supplying build material to a three-dimensional printing system. The apparatus comprises a rotatable vane.

BACKGROUND

Additive manufacturing techniques, such as three-dimensional (3D)printing, enable objects to be generated on a layer-by-layer basis. 3Dprinting techniques may generate layers of an object by formingsuccessive layers of a build material on a build or build platform, andselectively solidifying portions of each layer of the build material.

BRIEF DESCRIPTION

Examples will now be described, by way of non-limiting example only,with reference to the accompanying drawings, in which:

FIG. 1 is a simplified isometric illustration of a portion of a 3Dprinting system according to one example;

FIG. 2a is a simplified side view of a build material supply moduleaccording to one example;

FIG. 2b is a simplified side view of a build material supply moduleaccording to one example;

FIG. 3 is a block diagram of a controller;

FIG. 4 is a flow diagram outlining an example method according to oneexample;

FIG. 5 is a simplified side view illustration of a 3D printing systemaccording to one example; and

FIG. 6 is a simplified side view illustration of a 3D printing systemaccording to one example.

DETAILED DESCRIPTION

Some 3D printing systems use build material that have a powdered, orgranular, form. According to one example a suitable build material maybe a powdered semi-crystalline thermoplastic material. One suitablematerial may be Nylon 12, which is available, for example, fromSigma-Aldrich Co. LLC. Another suitable material may be PA 2200 which isavailable from Electro Optical Systems EOS GmbH.

In other examples other suitable build materials may be used. Suchmaterials may include, for example, powdered metal materials, powderedplastics materials, powdered composite materials, powdered ceramicmaterials, powdered glass materials, powdered resin material, powderedpolymer materials, and the like. Different powders may have differentcharacteristics, such as different average particle sizes, differentminimum and maximum particle sizes, different coefficient of friction,different angle of repose, and the like. In some examples non-powderedbuild materials may be used, such as gels, pastes, and slurries.

Such 3D printing systems typically provide, along a side of a buildplatform, a quantity of build material to be spread over the buildplatform to form a thin layer of build material on the build platform.Portions of the layer may then be solidified, using any suitablesolidification technique, such as fusing agent deposition and heatingsystems, binder agent deposition systems, laser sintering systems, andthe like.

During a 3D printing operation, an initial layer of build material maybe spread directly on the surface of a build platform, whereassubsequent layers of build material may be formed on a previously formedlayer of build material. Herein, reference to forming a layer of buildmaterial on the build platform may refer, depending on the context,either to forming a layer of build material directly on the surface ofthe build platform, or to forming a layer of build material on apreviously formed layer of build material.

Various examples will now be described that provide a compact andconvenient system for providing build material to be spread over a buildplatform, for example for use in the generation of 3D objects by a 3Dprinting system. Examples described herein enable a dose of apredetermined quantity of build material to be formed along the edge ofa build platform. The dose of build material may then be spread over thebuild, or support, platform using an appropriate build materialspreading mechanism. Forming a dose of build material may be useful, forexample, for reducing the amount of excess build material remainingafter a layer of build material has been formed, for ensuring thatsufficient build material is provided to enable a complete layer ofbuild material to be formed, and for reducing the amount of buildmaterial that could become airborne whilst forming a layer of buildmaterial.

Referring now to FIG. 1 there is shown an illustration of a portion of a3D printing system 100 according to one example. For clarity reasons notall the elements of the 3D printing system 100 are shown. For example,the illustrations shown herein do not show any specific build materialsolidification systems, although any suitable build materialsolidification systems may be used, such as fusing agent deposition andheating systems, binder agent deposition systems, laser sinteringsystems, and the like.

The system 100 comprises a build material supply module 102 from which aquantity of build material may be prepared to be spread across a buildplatform 104 by a horizontally movable build material spreader 108. Thespreader 108 may, in one example, be mounted on a suitable carriage organtry (not shown). The build platform 104 may be movable in the z-axis,as indicated by arrow 106, to enable it to be lowered by a small amountto enable each layer of build material to formed thereon. In the exampleshown the build material spreader 108 is a roller, although in otherexamples other suitable forms of spreader, such as a wiper blade, may beused. Build material is supplied to the supply module 102 from a buildmaterial store (not shown). In one example, as described later, thebuild material store may be located below the height of the supplymodule 102, although in other examples other configurations may be used.

The supply module 102 has a length that, in one example, issubstantially the same as the length of the build platform 104. In otherexamples, however, the supply module 102 may be longer or shorter thanthe build platform 104.

The supply module 102 forms a generally open container in which buildmaterial may be deposited, or delivered, and from which build materialmay be moved to enable it be spread over the build platform 104. In FIG.1, the foreground endplate of the supply module 102 is not shown so asto allow the internal structure of the supply module 102 to be visible.In the example shown the supply module 102 has a cross-section thatdefines an arc of circle. In the example shown the arc defines a portionof a circle that is greater than a semicircle. The top of the supplymodule 102 is about level with the top of the build platform 104,although the top of the build platform 104 will be lower than the top ofthe supply module when a layer of build material is spread thereover. Inother examples, the design of the supply module 102 may have a differentshape.

The supply module 102 further comprises a vane, or blade, 110 that isconnected to, or forms part of, a spindle 112, that is rotatable aboutthe axis 114. The rotation axis 114 of the vane 110 runs through thecentre of the circle that the cross-sectional arc shape of the supplymodule 102 defines.

The vane 110 has an angular form, comprising a first section 110 aimmediately adjacent to the spindle 112, and a distal second section 110b. The first section 110 a may be referred to as a build material returnsection, and the second section 110 b may be referred to as a buildmaterial support section. The angle formed by the first and secondsections 110 a and 110 b may be selected based on characteristics of abuild material, or of multiple build materials, with which the printingsystem 100 is to be used, as described in further detail below. In oneexample, when the second section 110 b is horizontal (in a ‘feedposition’), the first section 110 a slopes towards the spindle 112 at anacute angle which in one example may be between about 20 to 45 degreesbelow horizontal, although in other examples greater or smaller anglesmay be selected. The length of the first and second sections 110 a and110 b are chosen such that the free end of the section 110 b forms asubstantial seal against the curved inner surface of the supply module102 as the vane 110 is rotated.

In one example the vane 110 is formed as a single object, for examplethrough extrusion of a material, or through bending of a sheet ofmaterial. In this example, the first and second portions 110 a and 110 bof the vane are fixed relative to each other, and the angle between thefirst and second portions 110 a and 110 b is not adjustable. Such a vanehas mechanically simple design that has no moving parts, and thatenables the vane mechanism to function in a powdered build materialenvironment.

The vane 110 may be driven by any suitable drive mechanism (not shown),such as a stepper motor, rack and pinion arrangement, or the like andmay additionally be coupled to a position determination module (notshown), such as an angular encoder, to enable the angular position ofthe vane to be accurately controlled and determined.

Referring now to FIG. 2a , there is a shown a schematic cross-sectiondrawing of the supply module 102 and vane 110 according to an example. Aquantity of build material 202 has been delivered to the supply module102 and the vane 110 has been rotated through the build material 202 ina clock-wise direction, such that the second section 110 b of the vaneis in a horizontal feed position. In this position the second section110 b is level with the top of the supply module 102. Due to the shapeof the vane, as a volume of build material 204 is scooped up by therotating vane 110 the volume of build material is constrained at thedistal end of the second section 110 b of the vane against the internalside wall of the supply module 102. As the second section 110 b of thevane approaches the horizontal position the build material supported bythe second section 110 b of the vane starts to stabilize at its naturalangle of repose, and excess build material starts to fall away undergravity, sliding down the first portion 110 a of the vane and back intothe supply module 102. Since the excess build material slides down thefirst portion 110 a it has a slower speed than if it were to freefallunder gravity.

Once the second section 110 b of the vane is horizontal and the excessbuild material has fallen back into the supply module 202, the volume ofbuild material 204 supported by the second section 110 b of the vane isa substantially predetermined volume. The predetermined volume may bemodified, for a build material having a given angle of repose, bymodifying the depth of the second section 110 b of the vane. Using abuild material having a different angle of repose will also modify thepredetermined quantity. Depending on the volume of build material usedby the 3D printer 100 whilst processing each layer the parameters of thevane 110 may be chosen accordingly.

The first section 110 a of the vane plays an important role in returningexcess powder back to the build module 202 whilst reducing the amount ofbuild material that may become airborne. This is because once buildmaterial becomes airborne it can cause problems that may include, forexample: obscuring visual sensors; contamination of printheads used todeposit agents on the build material; causing an explosion risk; andenvironmental issues. Accordingly, by choosing a gentle slope of, forexample, less than 45 degrees, or less than 30 degrees, or less than 20degrees, reduces the speed at which excess build material is returned tothe supply module, and hence reduces the amount of build material thatbecomes airborne. The angle formed by the first section 110 a of thevane when the second section 110 b of the vane is horizontal may bechosen based on, for example, the angle of repose of the build materialused or other characteristics of the build material.

In some examples the first portion 110 a of the vane may continue beyondthe spindle 112, such that the distance any build material may free-fallback into the supply module 102 may be further reduced to even furtherreduce the amount of build material may become airborne. In this examplethe axis of rotation of the vane 110 may be within the build materialreturn section 110 a.

FIG. 2b shows a further example of a supply module 210. In this examplethe supply module 210 comprises a reciprocating build materialdistribution element 212. The build material distribution element 212may be controlled to reciprocate, or slide, along the base of the supplymodule 210, by a small amount to help distribute build material withinthe supply module 210, as described further below. In one example thebuild material distribution element 212 may be controlled to slide, orvibrate, by up to about 1 cm, although in other examples the buildmaterial distribution element may be controlled to slide by a greater orsmaller amount. In one example the build material distribution elementmay comprise a mesh-like structure and be driven by any suitable drivesystem, such as a motor.

In other examples a build material distribution element, such as buildmaterial distribution element 212 may be incorporated into the supplymodule 102 in a suitable manner.

Operation of the 3D printing system 100 is generally controlled by acontroller 116, as shown in greater detail in FIG. 3.

The controller 116 comprises a processor 302 coupled to a memory 304.The memory 304 stores build material supply management instructions 306that, when executed by the processor 302, control the 3D printing system100 to manage the supply of build material, as described herein.

Example operation of the 3D printing system 100 will now be describedwith reference to the flow diagram of FIG. 4 and the drawing of FIG. 5.

At 402, the controller 116 controls the delivery of build material tothe supply module 102. One example of how build material may bedelivered to the supply module 102 is shown in FIG. 5. In FIG. 5 isshown a build material store 502 comprising build material 504 and afeed channel 506 to move build material 504 from the build materialstore 502 to a delivery zone 508 within the supply module 512. The feedchannel 506 comprises a feed mechanism, such as an auger screw 510, orany other suitable feed mechanism.

In one example the build material feed mechanism 510 may be controlledto deliver a predetermined amount of build material to the supply module102. For example, if an auger screw mechanism is used as the feedmechanism, the number of rotations of the auger screw may be controlledto deliver the predetermined amount of powder.

The delivery zone 508 may be positioned at any suitable position alongthe length of the supply module 512, but in at least some examples thedelivery zone 508 does not extend substantially along the length of thesupply module. For example, the delivery zone may have a length that isless than about 10% of the length of the supply module 512 in someexamples.

The build material store 502 may, in one example, additionally include avibrator or compactor (not shown) to help ensure that build material 504within the build material store 502 compacts around the lower end of thefeed mechanism 510, to ensure a regular supply of build material to thefeed mechanism 510.

Having a build material store located generally beneath the buildplatform 104 and supply module 102 enables the footprint of such a 3Dprinting system to be reduced, compared to having a build material storelocated at one side of the 3D printing system.

In other examples, however, build material may be delivered to thesupply module 102 using other suitable configurations such as, forexample, from an overhead build material hopper.

At 404, the controller 116 controls a build material distributionelement 514 to reciprocate to evenly distribute the delivered buildmaterial 504 along the length of the supply module 512. In one example,as build material is being delivered to the supply module 512, thecontroller 116 moves the vane 516 to a position, such as a generallyvertical position. This allows the build material 508 to be distributedto a generally even level on both sides of the vane 516. In otherexamples the controller 116 may reciprocate the vane 516 to help theeven distribution of build material within the supply module 102

At 406, the controller 116 controls the vane 516 to move to the feedposition, i.e., such that the second portion of the vane is horizontal.As described above, as the vane 516 moves to the horizontal positionexcess build material may slide down the first portion of the vane 516and be returned to the supply module 512. Depending on the nature of thebuild material, by the time the vane 516 is moved to the feed positionthe quantity of build material supported by the second portion of thevane 516 will have stabilized, leaving a predetermined quantity of buildmaterial ready to be spread across the build platform 104. In oneexample, however, a short delay, for example less than 1 second, may beintroduced to allow build material supported by the second portion ofthe vane 516 to stabilize before the build material is spread across thebuild platform 104.

A yet further example is illustrated in FIG. 6, which shows a crosssectional illustration of a portion of a 3D printing system 600according to one example. In this example a pair of supply modules 602 aand 602 b are provided on opposite sides of a build platform 104. Thisexample enables build material to be supplied to either side of thebuild platform 104. Furthermore, any excess build material may bereturned to the opposite supply module.

In this way, coordination of the control of each supply module 602 a and602 b may provide enhanced efficiencies when the 3D printing system 600is configured to operate in a bi-directional manner. By bi-directionalis meant that a layer of build material may be formed on the buildplatform 104 by the build material spreader 108 using build materialfrom either of the build modules 602 a or 602 b. The 3D printing system600 may also be able to selectively solidify portions of a formed layerof build material whilst operating in either direction.

In one example the build platform 104 may be part of a removable buildmodule that may be insertable into the 3D printing system. Accordingly,reference herein to a build platform will be understood to generallyrefer to when such a build module is inserted into the 3D printingsystem.

Although examples of the vane described herein describe a vane having anangular form, in other examples the vane may comprise other forms, suchas comprising one or multiple curved portions. For example, the buildmaterial return portion may, in some examples, have a curved formed.

It will be appreciated that examples described herein can be realized inthe form of hardware, software or a combination of hardware andsoftware. Any such software may be stored in the form of volatile ornon-volatile storage such as, for example, a storage device like a ROM,whether erasable or rewritable or not, or in the form of memory such as,for example, RAM, memory chips, device or integrated circuits or on anoptically or magnetically readable medium such as, for example, a CD,DVD, magnetic disk or magnetic tape. It will be appreciated that thestorage devices and storage media are examples of machine-readablestorage that are suitable for storing a program or programs that, whenexecuted, implement examples described herein. Accordingly, someexamples provide a program comprising code for implementing a system ormethod as claimed in any preceding claim and a machine readable storagestoring such a program. Still further, some examples may be conveyedelectronically via any medium such as a communication signal carriedover a wired or wireless connection.

All of the features disclosed in this specification (including anyaccompanying claims, abstract and drawings), and/or all of the steps ofany method or process so disclosed, may be combined in any combination,except combinations where at least some of such features and/or stepsare mutually exclusive.

Each feature disclosed in this specification (including any accompanyingclaims, abstract and drawings), may be replaced by alternative featuresserving the same, equivalent or similar purpose, unless expressly statedotherwise. Thus, unless expressly stated otherwise, each featuredisclosed is one example only of a generic series of equivalent orsimilar features.

What is claimed is:
 1. A three-dimension printing system comprising: abuild material delivery system; a build material supply module; a buildmaterial distribution system; a build material spreader; and acontroller to: control the build material delivery system to deliverbuild material to the build material supply module; control the buildmaterial distribution system to distribute build material within thebuild material supply module; and control a rotatable vane within thebuild material supply module to move a portion of build material fromthe build material supply module to a horizontal feed position, the vanehaving a build material support section and a build material returnsection such that, as the vane is rotated to position the build materialsupport section horizontally, the build material return section slopesback into an interior of the build material supply module from an edgeof the build material support section that is opposite another edge ofthe build material support section that is then adjacent a buildplatform so that excess build material may slide down the build materialreturn section to return to the build material supply module and cause apredeterminable quantity of build material to be left on the buildmaterial support section.
 2. The system of claim 1, wherein a distal endof the vane forms a substantial seal against an inside of the supplymodule.
 3. The system of claim 1, wherein the build material deliverysystem delivers build material to a delivery zone within the supplymodule, the delivery zone have a length less than the length of thesupply module, and wherein the controller controls the build materialdistribution system to evenly distribute the build material along thelength of the supply module.
 4. The system of claim 1, wherein the anglebetween the build material support section and the build material returnsection is between about 20 and 45 degrees.
 5. The system of claim 1,wherein a quantity of build material left on the build material supportsection when in the feed position is based in part on a depth of thebuild material support section, and in part on characteristics of thebuild material.
 6. The system of claim 1, wherein an axis of rotation ofthe vane is a central axis of a cylindrically-shaped chamber within thebuild material supply module.
 7. The system of claim 1, furthercomprising a build material store located below the build materialsupply module, and wherein the build material delivery system is todeliver build material from the build material store to the buildmaterial supply module in a delivery zone within the build materialsupply module.
 8. The system of claim 1, wherein the build materialdistribution system comprises a reciprocating member disposed on abottom of the build material supply module, wherein the reciprocatingmember is to reciprocate along the bottom of the supply module.
 9. Thesystem of claim 1, wherein an angle between the build material supportsection of the vane and the build material return section of the vanecorresponds to a characteristic of the build material to be delivered.10. The system of claim 1, wherein the build material delivery systemcomprises an auger screw to deliver controlled amounts of build materialto the build material supply module.
 11. The apparatus of claim 1,wherein the build material spreader is to delay spreading of the buildmaterial for a period of time after the build material support sectionarrives in the feed position so as to allow for stabilization of thebuild material prior to spreading.
 12. A method of providing apredeterminable volume of build material for spreading over a buildplatform of a three-dimension printing system, comprising: deliveringbuild material to a build material supply module and distributing thebuild material evenly therein; and rotating a vane through buildmaterial in the supply module to position the vane in a feed position,wherein at the feed position, a first distal portion of the vane ishorizontal, and a second portion of the vane slopes back into aninterior of the build material supply module from an edge of the firstdistal portion that is opposite an edge of the first distal portionadjacent the build platform.
 13. The method of claim 12, wherein thesecond portion of the vane is contiguous with the first distal portionso that build material may slide from the first distal portion directlyonto the second portion under influence of gravity when the first distalportion of the vane is horizontal and in the feed position.
 14. Themethod of claim 12, wherein an angle between first distal portion andthe second distal portion of the vane is between 20 and 45 degrees andcorresponds to a characteristic of the build material to be delivered.15. The method of claim 12, further comprising delaying spreading of thebuild material for a period of time after the first distal portionarrives in the feed position so as to allow for stabilization of thebuild material prior to spreading.
 16. Apparatus for supplying buildmaterial to a three-dimensional printing system, comprising: a buildmaterial supply module; and a rotatable vane to move a portion of buildmaterial from the build material supply module to a feed position, thevane comprising a build material support section and a build materialreturn section, the vane arranged having a common surface that extendsover the build material support section and build material returnsection such that, as the build material support section is moved to thefeed position, excess build material may slide down from the buildmaterial support section on the common surface to the build materialreturn section and return to an interior of the build material supplymodule, thereby leaving a predeterminable quantity of build material onthe build material support section.
 17. The apparatus of claim 16,wherein an axis of rotation of the vane is a central axis of acylindrically-shaped chamber within the build material supply module.18. The apparatus of claim 16, wherein the feed position is where thebuild material support section is horizontal.
 19. The apparatus of claim16, further comprising a build material spreader to spread buildmaterial from the vane, when in the feed position, over a buildplatform.
 20. The apparatus of claim 19, wherein the spreader is todelay spreading of the build material for a period of time after thebuild material support section arrives in the feed position so as toallow for stabilization of the build material prior to spreading.